/*
 * This file is part of EasyRPG Player.
 *
 * EasyRPG Player is free software: you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation, either version 3 of the License, or
 * (at your option) any later version.
 *
 * EasyRPG Player is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with EasyRPG Player. If not, see <http://www.gnu.org/licenses/>.
 */

#include "maniac_patch.h"

#include "input.h"
#include "game_actors.h"
#include "game_interpreter_control_variables.h"
#include "game_map.h"
#include "game_interpreter.h"
#include "game_party.h"
#include "game_switches.h"
#include "game_variables.h"
#include "main_data.h"
#include "output.h"
#include "player.h"

#include <lcf/reader_util.h>
#include <vector>

/*
The following operations are unsupported:

All array functions (Array, Range and Subscript):
They could be implemented but are not very useful

All Inplace functions:
These functions are disabled when EasyRpg Extensions are active.
Inplace assigns to variables while the ControlVariables event command is executed.
This violates how the command is supposed to work because more variables than the target variables can be set.
*/

namespace {
	enum class Op {
		Null = 0,
		U8,
		U16,
		S32,
		UX8,
		UX16,
		SX32,
		Var = 8,
		Switch,
		VarIndirect = 13,
		SwitchIndirect,
		Array = 19,
		Negate = 24,
		Not,
		Flip,
		AssignInplace = 34,
		AddInplace,
		SubInplace,
		MulInplace,
		DivInplace,
		ModInplace,
		BitOrInplace,
		BitAndInplace,
		BitXorInplace,
		BitShiftLeftInplace,
		BitShiftRightInplace,
		Add = 48,
		Sub,
		Mul,
		Div,
		Mod,
		BitOr,
		BitAnd,
		BitXor,
		BitShiftLeft,
		BitShiftRight,
		Equal,
		GreaterEqual,
		LessEqual,
		Greater,
		Less,
		NotEqual,
		Or,
		And,
		Range,
		Subscript,
		Ternary = 72,
		Function = 78
	};

	enum class Fn {
		Rand = 0,
		Item,
		Event,
		Actor,
		Party,
		Enemy,
		Misc,
		Pow,
		Sqrt,
		Sin,
		Cos,
		Atan2,
		Min,
		Max,
		Abs,
		Clamp,
		Muldiv,
		Divmul,
		Between
	};
}

struct ProcessAssignmentRet {
	Op op = Op::Null;
	int id = 0;

	int fetch() const {
		switch (op) {
		case Op::Var:
			return Main_Data::game_variables->Get(id);
		case Op::Switch:
			return Main_Data::game_switches->Get(id);
		case Op::VarIndirect: {
			return Main_Data::game_variables->GetIndirect(id);
		}
		case Op::SwitchIndirect: {
			int var = Main_Data::game_variables->GetIndirect(id);
			return Main_Data::game_switches->Get(var);
		}
		default:
			Output::Warning("Maniac: Expression assignment {} is not a lvalue", static_cast<int>(op));
			return 0;
		}
	}

	int assign(int value) const {
		if (Player::HasEasyRpgExtensions()) {
			Output::Warning("Maniac: Inplace assignments are not allowed in expressions when running in EasyRpg Mode");
			return fetch();
		}

		switch (op) {
		case Op::Var:
			Game_Map::SetNeedRefreshForVarChange(id);
			return Main_Data::game_variables->Set(id, value);
		case Op::Switch:
			Game_Map::SetNeedRefreshForSwitchChange(id);
			return Main_Data::game_switches->Set(id, value > 0);
		case Op::VarIndirect: {
			int var = Main_Data::game_variables->GetIndirect(id);
			Game_Map::SetNeedRefreshForVarChange(var);
			return Main_Data::game_variables->Set(var, value);
		}
		case Op::SwitchIndirect: {
			int var = Main_Data::game_variables->GetIndirect(id);
			Game_Map::SetNeedRefreshForSwitchChange(var);
			return Main_Data::game_switches->Set(var, value > 0);
		}
		default:
			Output::Warning("Maniac: Expression assignment {} is not a lvalue", static_cast<int>(op));
			return 0;
		}
	}
};

ProcessAssignmentRet ProcessAssignment(std::vector<int32_t>::iterator& it, std::vector<int32_t>::iterator end, const Game_BaseInterpreterContext& ip);

int Process(std::vector<int32_t>::iterator& it, std::vector<int32_t>::iterator end, const Game_BaseInterpreterContext& ip) {
	int value = 0;
	int imm = 0;
	int imm2 = 0;
	int imm3 = 0;

	if (it == end) {
		return 0;
	}

	auto op = static_cast<Op>(*it);
	++it;

	// When entering the switch it is on the first argument
	switch (op) {
		case Op::Null:
			it++;
			return 0;
		case Op::U8:
		case Op::UX8:
			value = *it++;
			return value;
		case Op::U16:
		case Op::UX16:
			imm = *it++;
			if (it == end) {
				return 0;
			}
			imm2 = *it++;
			value = (imm2 << 8) + imm;
			return value;
		case Op::S32:
		case Op::SX32:
			imm = *it++;
			if (it == end) {
				return 0;
			}
			imm2 = *it++;
			if (it == end) {
				return 0;
			}
			imm3 = *it++;
			if (it == end) {
				return 0;
			}
			value = *it++;
			value = (value << 24) + (imm3 << 16) + (imm2 << 8) + imm;
			return value;
		case Op::Var:
			imm = Process(it, end, ip);
			return Main_Data::game_variables->Get(imm);
		case Op::Switch:
			imm = Process(it, end, ip);
			return Main_Data::game_switches->GetInt(imm);
		case Op::VarIndirect:
			imm = Process(it, end, ip);
			return Main_Data::game_variables->GetIndirect(imm);
		case Op::SwitchIndirect:
			imm = Process(it, end, ip);
			return Main_Data::game_switches->GetInt(Main_Data::game_variables->Get(imm));
		case Op::Negate:
			imm = Process(it, end, ip);
			return -imm;
		case Op::Not:
			imm = Process(it, end, ip);
			return !imm ? 0 : 1;
		case Op::Flip:
			imm = Process(it, end, ip);
			return ~imm;
		case Op::AssignInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(imm2);
		}
		case Op::AddInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(static_cast<int32_t>(Utils::Clamp<int64_t>(static_cast<int64_t>(ret.fetch()) + imm2, std::numeric_limits<int32_t>::min(), std::numeric_limits<int32_t>::max())));
		}
		case Op::SubInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(static_cast<int32_t>(Utils::Clamp<int64_t>(static_cast<int64_t>(ret.fetch()) - imm2, std::numeric_limits<int32_t>::min(), std::numeric_limits<int32_t>::max())));
		}
		case Op::MulInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(static_cast<int32_t>(Utils::Clamp<int64_t>(static_cast<int64_t>(ret.fetch()) * imm2, std::numeric_limits<int32_t>::min(), std::numeric_limits<int32_t>::max())));
		}
		case Op::DivInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			if (imm2 == 0) {
				return ret.fetch();
			}
			return ret.assign(ret.fetch() / imm2);
		}
		case Op::ModInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			if (imm2 == 0) {
				return ret.fetch();
			}
			return ret.assign(ret.fetch() % imm2);
		}
		case Op::BitOrInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(ret.fetch() | imm2);
		}
		case Op::BitAndInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(ret.fetch() & imm2);
		}
		case Op::BitXorInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(ret.fetch() ^ imm2);
		}
		case Op::BitShiftLeftInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(ret.fetch() << imm2);
		}
		case Op::BitShiftRightInplace: {
			auto ret = ProcessAssignment(it, end, ip);
			imm2 = Process(it, end, ip);
			return ret.assign(ret.fetch() >> imm2);
		}
		case Op::Add:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return static_cast<int32_t>(Utils::Clamp<int64_t>(static_cast<int64_t>(imm) + imm2, std::numeric_limits<int32_t>::min(), std::numeric_limits<int32_t>::max()));
		case Op::Sub:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return static_cast<int32_t>(Utils::Clamp<int64_t>(static_cast<int64_t>(imm) - imm2, std::numeric_limits<int32_t>::min(), std::numeric_limits<int32_t>::max()));
		case Op::Mul:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return static_cast<int32_t>(Utils::Clamp<int64_t>(static_cast<int64_t>(imm) * imm2, std::numeric_limits<int32_t>::min(), std::numeric_limits<int32_t>::max()));
		case Op::Div:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			if (imm2 == 0) {
				return imm;
			}
			return imm / imm2;
		case Op::Mod:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			if (imm2 == 0) {
				return imm;
			}
			return imm % imm2;
		case Op::BitOr:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm | imm2;
		case Op::BitAnd:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm & imm2;
		case Op::BitXor:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm ^ imm2;
		case Op::BitShiftLeft:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm << imm2;
		case Op::BitShiftRight:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm >> imm2;
		case Op::Equal:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm == imm2 ? 1 : 0;
		case Op::GreaterEqual:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm >= imm2 ? 1 : 0;
		case Op::LessEqual:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm <= imm2 ? 1 : 0;
		case Op::Greater:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm > imm2 ? 1 : 0;
		case Op::Less:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm < imm2 ? 1 : 0;
		case Op::NotEqual:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return imm != imm2 ? 1 : 0;
		case Op::Or:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return !!imm || !!imm2 ? 1 : 0;
		case Op::And:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			return !!imm && !!imm2 ? 1 : 0;
		case Op::Ternary:
			imm = Process(it, end, ip);
			imm2 = Process(it, end, ip);
			imm3 = Process(it, end, ip);
			return imm != 0 ? imm2 : imm3;
		case Op::Function:
			imm = *it++; // function
			imm2 = *it++; // arguments

			if ((imm2 & 0x80) != 0) {
				// Argument count is 4 bytes, that mode is not supported
				Output::Warning("Maniac: Expression func long args unsupported");
				return 0;
			}

			switch (static_cast<Fn>(imm)) {
				case Fn::Rand:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression rnd args {} != 2", imm2);
						return 0;
					}
					imm3 = Process(it, end, ip);
					return ControlVariables::Random(Process(it, end, ip), imm3);
				case Fn::Item:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression item args {} != 2", imm2);
						return 0;
					}
					imm3 = Process(it, end, ip);
					return ControlVariables::Item(Process(it, end, ip), imm3);
				case Fn::Event:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression event args {} != 2", imm2);
						return 0;
					}
					imm3 = Process(it, end, ip);
					return ControlVariables::Event(Process(it, end, ip), imm3, ip);
				case Fn::Actor:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression actor args {} != 2", imm2);
						return 0;
					}
					return ControlVariables::Actor(Process(it, end, ip), imm3);
				case Fn::Party:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression member args {} != 2", imm2);
						return 0;
					}
					imm3 = Process(it, end, ip);
					return ControlVariables::Party(Process(it, end, ip), imm3);
				case Fn::Enemy:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression enemy args {} != 2", imm2);
						return 0;
					}
					imm3 = Process(it, end, ip);
					return ControlVariables::Enemy(Process(it, end, ip), imm3);
					break;
				case Fn::Misc:
					if (imm2 != 1) {
						Output::Warning("Maniac: Expression misc args {} != 1", imm2);
						return 0;
					}
					return ControlVariables::Other(Process(it, end, ip));
				case Fn::Pow:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression pow args {} != 2", imm2);
						return 0;
					}
					return ControlVariables::Pow(Process(it, end, ip), Process(it, end, ip));
				case Fn::Sqrt:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression sqrt args {} != 2", imm2);
						return 0;
					}
					return ControlVariables::Sqrt(Process(it, end, ip), Process(it, end, ip));
				case Fn::Sin:
					if (imm2 != 3) {
						Output::Warning("Maniac: Expression sin args {} != 3", imm2);
						return 0;
					}
					return ControlVariables::Sin(Process(it, end, ip), Process(it, end, ip), Process(it, end, ip));
				case Fn::Cos:
					if (imm2 != 3) {
						Output::Warning("Maniac: Expression cos args {} != 3", imm2);
						return 0;
					}
					return ControlVariables::Cos(Process(it, end, ip), Process(it, end, ip), Process(it, end, ip));
				case Fn::Atan2:
					if (imm2 != 3) {
						Output::Warning("Maniac: Expression atan2 args {} != 3", imm2);
						return 0;
					}
					return ControlVariables::Atan2(Process(it, end, ip), Process(it, end, ip), Process(it, end, ip));
				case Fn::Min:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression min args {} != 2", imm2);
						return 0;
					}
					return ControlVariables::Min(Process(it, end, ip), Process(it, end, ip));
				case Fn::Max:
					if (imm2 != 2) {
						Output::Warning("Maniac: Expression max args {} != 2", imm2);
						return 0;
					}
					return ControlVariables::Max(Process(it, end, ip), Process(it, end, ip));
				case Fn::Abs:
					if (imm2 != 1) {
						Output::Warning("Maniac: Expression abs args {} != 1", imm2);
						return 0;
					}
					return ControlVariables::Abs(Process(it, end, ip));
				case Fn::Clamp:
					if (imm2 != 3) {
						Output::Warning("Maniac: Expression clamp args {} != 3", imm2);
						return 0;
					}
					return ControlVariables::Clamp(Process(it, end, ip), Process(it, end, ip), Process(it, end, ip));
				case Fn::Muldiv:
					if (imm2 != 3) {
						Output::Warning("Maniac: Expression muldiv args {} != 3", imm2);
						return 0;
					}
					return ControlVariables::Muldiv(Process(it, end, ip), Process(it, end, ip), Process(it, end, ip));
				case Fn::Divmul:
					if (imm2 != 3) {
						Output::Warning("Maniac: Expression divmul args {} != 3", imm2);
						return 0;
					}
					return ControlVariables::Divmul(Process(it, end, ip), Process(it, end, ip), Process(it, end, ip));
				case Fn::Between:
					if (imm2 != 3) {
						Output::Warning("Maniac: Expression between args {} != 3", imm2);
						return 0;
					}
					return ControlVariables::Between(Process(it, end, ip), Process(it, end, ip), Process(it, end, ip));
				default:
					Output::Warning("Maniac: Expression Unknown Func {}", imm);
					for (int i = 0; i < imm2; ++i) {
						Process(it, end, ip);
					}
					return 0;
			}
		default:
			Output::Warning("Maniac: Expression contains unsupported operation {}", static_cast<int>(op));
			return 0;
	}
}

ProcessAssignmentRet ProcessAssignment(std::vector<int32_t>::iterator& it, std::vector<int32_t>::iterator end, const Game_BaseInterpreterContext& ip) {
	// Like process but it remembers the type (Variable or Switch) without evaluating it to allow assignments
	int imm = 0;

	if (it == end) {
		return {Op::Null, 0};
	}

	auto op = static_cast<Op>(*it);
	++it;

	// When entering the switch it is on the first argument
	switch (op) {
		case Op::Var:
		case Op::Switch:
		case Op::VarIndirect:
		case Op::SwitchIndirect:
			imm = Process(it, end, ip);
			return {op, imm};
		default:
			--it; // back on the op as op is fetched again by Process
			imm = Process(it, end, ip);
			return {op, imm};
	}
}

int32_t ManiacPatch::ParseExpression(Span<const int32_t> op_codes, const Game_BaseInterpreterContext& interpreter) {
	std::vector<int32_t> ops;
	for (auto &o: op_codes) {
		auto uo = static_cast<uint32_t>(o);
		ops.push_back(static_cast<int32_t>(uo & 0x000000FF));
		ops.push_back(static_cast<int32_t>((uo & 0x0000FF00) >> 8));
		ops.push_back(static_cast<int32_t>((uo & 0x00FF0000) >> 16));
		ops.push_back(static_cast<int32_t>((uo & 0xFF000000) >> 24));
	}
	auto beg = ops.begin();
	return Process(beg, ops.end(), interpreter);
}

std::array<bool, 50> ManiacPatch::GetKeyRange() {
	std::array<Input::Keys::InputKey, 50> keys = {
		Input::Keys::A,
		Input::Keys::B,
		Input::Keys::C,
		Input::Keys::D,
		Input::Keys::E,
		Input::Keys::F,
		Input::Keys::G,
		Input::Keys::H,
		Input::Keys::I,
		Input::Keys::J,
		Input::Keys::K,
		Input::Keys::L,
		Input::Keys::M,
		Input::Keys::N,
		Input::Keys::O,
		Input::Keys::P,
		Input::Keys::Q,
		Input::Keys::R,
		Input::Keys::S,
		Input::Keys::T,
		Input::Keys::U,
		Input::Keys::V,
		Input::Keys::W,
		Input::Keys::X,
		Input::Keys::Y,
		Input::Keys::Z,
		Input::Keys::N0,
		Input::Keys::N1,
		Input::Keys::N2,
		Input::Keys::N3,
		Input::Keys::N4,
		Input::Keys::N5,
		Input::Keys::N6,
		Input::Keys::N7,
		Input::Keys::N8,
		Input::Keys::N9,
		Input::Keys::LEFT,
		Input::Keys::UP,
		Input::Keys::RIGHT,
		Input::Keys::DOWN,
		Input::Keys::RETURN,
		Input::Keys::SHIFT,
		Input::Keys::CTRL,
		Input::Keys::ALT,
		Input::Keys::SPACE,
#if defined(USE_MOUSE) && defined(SUPPORT_MOUSE)
		Input::Keys::MOUSE_LEFT,
		Input::Keys::MOUSE_RIGHT,
		Input::Keys::MOUSE_MIDDLE,
		Input::Keys::MOUSE_SCROLLUP,
		Input::Keys::MOUSE_SCROLLDOWN
#else
		Input::Keys::NONE,
		Input::Keys::NONE,
		Input::Keys::NONE,
		Input::Keys::NONE,
		Input::Keys::NONE
#endif
	};

	std::array<bool, 50> pressed = {};

	for (size_t i = 0; i < pressed.size(); ++i) {
		pressed[i] = Input::IsRawKeyPressed(keys[i]);
	}

	return pressed;
}

bool ManiacPatch::GetKeyState(uint32_t key_id) {
	Input::Keys::InputKey key;

	// see https://docs.microsoft.com/en-us/windows/win32/inputdev/virtual-key-codes
	switch (key_id) {
#if defined(USE_MOUSE) && defined(SUPPORT_MOUSE)
		case 0x1: key = Input::Keys::MOUSE_LEFT; break;
		case 0x2: key = Input::Keys::MOUSE_RIGHT; break;
		case 0x4: key = Input::Keys::MOUSE_MIDDLE; break;
		case 0x5: key = Input::Keys::MOUSE_XBUTTON1; break;
		case 0x6: key = Input::Keys::MOUSE_XBUTTON2; break;
#endif
		case 0x8: key = Input::Keys::BACKSPACE; break;
		case 0x9: key = Input::Keys::TAB; break;
		case 0xD: key = Input::Keys::RETURN; break;
		case 0x10: key = Input::Keys::SHIFT; break;
		case 0x11: key = Input::Keys::CTRL; break;
		case 0x12: key = Input::Keys::ALT; break;
		case 0x13: key = Input::Keys::PAUSE; break;
		case 0x14: key = Input::Keys::CAPS_LOCK; break;
		case 0x1B: key = Input::Keys::ESCAPE; break;
		case 0x20: key = Input::Keys::SPACE; break;
		case 0x21: key = Input::Keys::PGUP; break;
		case 0x22: key = Input::Keys::PGDN; break;
		case 0x23: key = Input::Keys::ENDS; break;
		case 0x24: key = Input::Keys::HOME; break;
		case 0x25: key = Input::Keys::LEFT; break;
		case 0x26: key = Input::Keys::UP; break;
		case 0x27: key = Input::Keys::RIGHT; break;
		case 0x28: key = Input::Keys::DOWN; break;
		case 0x2D: key = Input::Keys::INSERT; break;
		case 0x2E: key = Input::Keys::DEL; break;
		case 0x30: key = Input::Keys::N0; break;
		case 0x31: key = Input::Keys::N1; break;
		case 0x32: key = Input::Keys::N2; break;
		case 0x33: key = Input::Keys::N3; break;
		case 0x34: key = Input::Keys::N4; break;
		case 0x35: key = Input::Keys::N5; break;
		case 0x36: key = Input::Keys::N6; break;
		case 0x37: key = Input::Keys::N7; break;
		case 0x38: key = Input::Keys::N8; break;
		case 0x39: key = Input::Keys::N9; break;
		case 0x41: key = Input::Keys::A; break;
		case 0x42: key = Input::Keys::B; break;
		case 0x43: key = Input::Keys::C; break;
		case 0x44: key = Input::Keys::D; break;
		case 0x45: key = Input::Keys::E; break;
		case 0x46: key = Input::Keys::F; break;
		case 0x47: key = Input::Keys::G; break;
		case 0x48: key = Input::Keys::H; break;
		case 0x49: key = Input::Keys::I; break;
		case 0x4A: key = Input::Keys::J; break;
		case 0x4B: key = Input::Keys::K; break;
		case 0x4C: key = Input::Keys::L; break;
		case 0x4D: key = Input::Keys::M; break;
		case 0x4E: key = Input::Keys::N; break;
		case 0x4F: key = Input::Keys::O; break;
		case 0x50: key = Input::Keys::P; break;
		case 0x51: key = Input::Keys::Q; break;
		case 0x52: key = Input::Keys::R; break;
		case 0x53: key = Input::Keys::S; break;
		case 0x54: key = Input::Keys::T; break;
		case 0x55: key = Input::Keys::U; break;
		case 0x56: key = Input::Keys::V; break;
		case 0x57: key = Input::Keys::W; break;
		case 0x58: key = Input::Keys::X; break;
		case 0x59: key = Input::Keys::Y; break;
		case 0x5A: key = Input::Keys::Z; break;
		case 0x60: key = Input::Keys::KP0; break;
		case 0x61: key = Input::Keys::KP1; break;
		case 0x62: key = Input::Keys::KP2; break;
		case 0x63: key = Input::Keys::KP3; break;
		case 0x64: key = Input::Keys::KP4; break;
		case 0x65: key = Input::Keys::KP5; break;
		case 0x66: key = Input::Keys::KP6; break;
		case 0x67: key = Input::Keys::KP7; break;
		case 0x68: key = Input::Keys::KP8; break;
		case 0x69: key = Input::Keys::KP9; break;
		case 0x6A: key = Input::Keys::KP_MULTIPLY; break;
		case 0x6B: key = Input::Keys::KP_ADD; break;
		case 0x6D: key = Input::Keys::KP_SUBTRACT; break;
		case 0x6E: key = Input::Keys::KP_PERIOD; break;
		case 0x6F: key = Input::Keys::KP_DIVIDE; break;
		case 0x70: key = Input::Keys::F1; break;
		case 0x71: key = Input::Keys::F2; break;
		case 0x72: key = Input::Keys::F3; break;
		case 0x73: key = Input::Keys::F4; break;
		case 0x74: key = Input::Keys::F5; break;
		case 0x75: key = Input::Keys::F6; break;
		case 0x76: key = Input::Keys::F7; break;
		case 0x77: key = Input::Keys::F8; break;
		case 0x78: key = Input::Keys::F9; break;
		case 0x79: key = Input::Keys::F10; break;
		case 0x7A: key = Input::Keys::F11; break;
		case 0x7B: key = Input::Keys::F12; break;
		case 0x90: key = Input::Keys::NUM_LOCK; break;
		case 0x91: key = Input::Keys::SCROLL_LOCK; break;
		case 0xA0: key = Input::Keys::LSHIFT; break;
		case 0xA1: key = Input::Keys::RSHIFT; break;
		case 0xA2: key = Input::Keys::LCTRL; break;
		case 0xA3: key = Input::Keys::RCTRL; break;
		default:
			Output::Debug("Maniac KeyInputProcEx: Unsupported keycode {}", key_id);
			key = Input::Keys::NONE;
			break;
	}

	return Input::IsRawKeyPressed(key);



}

bool ManiacPatch::CheckString(StringView str_l, StringView str_r, int op, bool ignore_case) {
	auto check = [op](const auto& l, const auto& r) {
		switch (op) {
			case 0: // eq
				return l == r;
			case 2: // contains (l contains r)
				return l.find(r) != std::string::npos;
			case 1: // neq
				return l != r;
			case 3: // notContains (l does not contain r)
				return l.find(r) == std::string::npos;
			default:
				return false;
		}
	};

	if (ignore_case) {
		std::string str_l_lower = Utils::LowerCase(str_l);
		std::string str_r_lower = Utils::LowerCase(str_r);
		return check(str_l_lower, str_r_lower);
	}

	return check(str_l, str_r);
}

StringView ManiacPatch::GetLcfName(int data_type, int id, bool is_dynamic) {
	auto get_name = [&id](StringView type, const auto& vec) -> StringView {
		auto* data = lcf::ReaderUtil::GetElement(vec, id);
		if (!data) {
			Output::Warning("Unable to read {} name: {}", type, id);
			return {};
		}
		return data->name;
	};

	switch (data_type)
	{
	case 0:  //.actor[a].name
		if (is_dynamic) {
			auto actor = Main_Data::game_actors->GetActor(id);
			if (actor != nullptr) {
				return actor->GetName();
			}
		}
		else {
			return get_name("Actor", lcf::Data::actors);
		}
		break;
	case 1:	 return get_name("Skill", lcf::Data::skills);   //.skill[a].name
	case 2:	 return get_name("Item", lcf::Data::items);   //.item[a].name
	case 3:	 return get_name("Enemy", lcf::Data::enemies);   //.enemy[a].name
	case 4:	 return get_name("Troop", lcf::Data::troops);   //.troop[a].name
	case 5:	 return get_name("Terrain", lcf::Data::terrains);   //.terrain[a].name
	case 6:	 return get_name("Attribute", lcf::Data::attributes);   //.element[a].name
	case 7:	 return get_name("State", lcf::Data::states);   //.state[a].name
	case 8:	 return get_name("Animation", lcf::Data::animations);   //.anim[a].name
	case 9:	 return get_name("Chipset", lcf::Data::chipsets);   //.tileset[a].name
	case 10: return Main_Data::game_switches->GetName(id);   //.s[a].name
	case 11: return Main_Data::game_variables->GetName(id);   //.v[a].name
	case 12: return {};  // FIXME: .t[a].name -- not sure how to get this for now
	case 13: //.cev[a].name
	{
		// assuming the vector of common events here is ordered by common event ID
		if (static_cast<int>(Game_Map::GetCommonEvents().size()) >= id) {
			return Game_Map::GetCommonEvents()[id - 1].GetName();
		}
		break;
	}
	case 14: return get_name("Class", lcf::Data::classes);   //.class[a].name
	case 15: return get_name("BattlerAnimation", lcf::Data::battleranimations);   //.anim2[a].name
	case 16: return Game_Map::GetMapName(id);   //.map[a].name
	case 17:   //.mev[a].name
	{
		auto map = Game_Map::GetEvent(id);
		if (map != nullptr) {
			return map->GetName();
		}
		break;
	}
	case 18: //.member[a].name, index starts from 0
	{
		auto actor = Main_Data::game_party->GetActor(id);
		if (actor != nullptr) {
			if (is_dynamic) {
				return actor->GetName();
			}
			else {
				id = actor->GetId();
				return get_name("Actor", lcf::Data::actors);
			}
		}
		break;
	}
	}

	Output::Warning("GetLcfName: Unsupported data_type {} {}", data_type, id);
	return {};
}

StringView ManiacPatch::GetLcfDescription(int data_type, int id, bool is_dynamic) {
	auto get_desc = [id](StringView type, const auto& vec) -> StringView {
		auto* data = lcf::ReaderUtil::GetElement(vec, id);
		if (!data) {
			Output::Warning("Unable to read {} description: {}", type, id);
			return {};
		}
		if constexpr (std::is_same_v<typename std::decay_t<decltype(vec)>::value_type, lcf::rpg::Actor>) {
			return data->title;
		} else {
			return data->description;
		}
	};

	switch (data_type)
	{
	case 0:  //.actor[a].desc
		if (is_dynamic) {
			auto actor = Main_Data::game_actors->GetActor(id);
			if (actor != nullptr) {
				return actor->GetTitle();
			}
		}
		else {
			return get_desc("Actor", lcf::Data::actors);
		}
		break;
	case 1: return get_desc("Skill", lcf::Data::skills); //.skill[a].desc
	case 2: return get_desc("Item", lcf::Data::items); //.item[a].desc
	case 18: //.member[a].desc
	{
		auto actor = Main_Data::game_party->GetActor(id);
		if (actor != nullptr) {
			if (is_dynamic) {
				return actor->GetTitle();
			}
			else {
				id = actor->GetId();
				return get_desc("Actor", lcf::Data::actors);
			}
		}
		break;
	}
	}

	Output::Warning("GetLcfDescription: Unsupported data_type {} {}", data_type, id);
	return {};
}
